CN106444680A - Building power saving control system based on ZigBee communication technology, and operating method of the same - Google Patents

Building power saving control system based on ZigBee communication technology, and operating method of the same Download PDF

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Publication number
CN106444680A
CN106444680A CN201610954528.1A CN201610954528A CN106444680A CN 106444680 A CN106444680 A CN 106444680A CN 201610954528 A CN201610954528 A CN 201610954528A CN 106444680 A CN106444680 A CN 106444680A
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cpu
temperature
module
parts
zigbee communication
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CN106444680B (en
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张刚
侯文宝
李德路
刘志坚
陈宏振
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Jiangsu elite heating and cooling equipment Engineering Co.,Ltd.
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Jiangsu Institute of Architectural Technology
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    • GPHYSICS
    • G05CONTROLLING; REGULATING
    • G05BCONTROL OR REGULATING SYSTEMS IN GENERAL; FUNCTIONAL ELEMENTS OF SUCH SYSTEMS; MONITORING OR TESTING ARRANGEMENTS FOR SUCH SYSTEMS OR ELEMENTS
    • G05B19/00Programme-control systems
    • G05B19/02Programme-control systems electric
    • G05B19/418Total factory control, i.e. centrally controlling a plurality of machines, e.g. direct or distributed numerical control [DNC], flexible manufacturing systems [FMS], integrated manufacturing systems [IMS] or computer integrated manufacturing [CIM]
    • G05B19/4185Total factory control, i.e. centrally controlling a plurality of machines, e.g. direct or distributed numerical control [DNC], flexible manufacturing systems [FMS], integrated manufacturing systems [IMS] or computer integrated manufacturing [CIM] characterised by the network communication
    • G05B19/4186Total factory control, i.e. centrally controlling a plurality of machines, e.g. direct or distributed numerical control [DNC], flexible manufacturing systems [FMS], integrated manufacturing systems [IMS] or computer integrated manufacturing [CIM] characterised by the network communication by protocol, e.g. MAP, TOP
    • GPHYSICS
    • G05CONTROLLING; REGULATING
    • G05BCONTROL OR REGULATING SYSTEMS IN GENERAL; FUNCTIONAL ELEMENTS OF SUCH SYSTEMS; MONITORING OR TESTING ARRANGEMENTS FOR SUCH SYSTEMS OR ELEMENTS
    • G05B15/00Systems controlled by a computer
    • G05B15/02Systems controlled by a computer electric
    • GPHYSICS
    • G05CONTROLLING; REGULATING
    • G05BCONTROL OR REGULATING SYSTEMS IN GENERAL; FUNCTIONAL ELEMENTS OF SUCH SYSTEMS; MONITORING OR TESTING ARRANGEMENTS FOR SUCH SYSTEMS OR ELEMENTS
    • G05B2219/00Program-control systems
    • G05B2219/20Pc systems
    • G05B2219/26Pc applications
    • G05B2219/2642Domotique, domestic, home control, automation, smart house
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02PCLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
    • Y02P80/00Climate change mitigation technologies for sector-wide applications
    • Y02P80/10Efficient use of energy, e.g. using compressed air or pressurized fluid as energy carrier

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  • Engineering & Computer Science (AREA)
  • Agricultural Chemicals And Associated Chemicals (AREA)
  • General Engineering & Computer Science (AREA)
  • Physics & Mathematics (AREA)
  • General Physics & Mathematics (AREA)
  • Automation & Control Theory (AREA)
  • Manufacturing & Machinery (AREA)
  • Quality & Reliability (AREA)

Abstract

The invention discloses a building power saving control system based on ZigBee communication technology, and an operating method of the same. The building power saving control system based on ZigBee communication technology is formed by a central processing unit, a temperature induction module, a luminosity induction unit, an electromagnetic induction wafer, a ZigBee communication module, and a remote monitoring module, wherein the temperature induction module is arranged on an indoor wall; the luminosity induction unit is fixedly arranged on an indoor ceiling; the electromagnetic induction wafer is fixedly arranged on the top right corner area of each office table; the ZigBee communication module is interactively connected with the central processing unit; and the remote monitoring module is connected with the ZigBee communication module through remote control. The building power saving control system based on ZigBee communication technology is high in the automation degree, can automatically adjust the indoor temperature and the luminance, can intelligently manage the number of electric lamps to turn on, and uses the ZigBee communication technology to realize remote monitoring management.

Description

A kind of building electricity-saving control system based on ZigBee communication technology and its method of work
Technical field
The invention belongs to building energy-saving application field is and in particular to a kind of building economize on electricity based on ZigBee communication technology is controlled System processed and its method of work.
Background technology
" energy-conservation, intelligence science and technology and aesthetics, the theme of 21 century building industry." in recent years, the high speed with domestic city is sent out Exhibition, the continuous improvement of the economic quickly flourishing and gentle environmental quality requirement of people's opposite running water, office building, religion in city Room, factory lamp place power consumption are increasing, and power saving is urgently to be resolved hurrily.According to statistics, China's year electric consumption on lighting amount accounts for total generating The 10% about of amount, and based on inefficient illumination, energy-saving potential is very big.In specific works, electric energy saving design can neither To sacrifice building function, infringement use demand increases investment as cost, nor blindly, is energy-conservation and energy-conservation.Therefore, for solving The big problem of traditional energy-saving technique energy waste, New Generation of Building Electric technology is attempt to using various advanced control modes Traditional architecture lighting apparatus is effectively controlled.
In daily life, people mostly adopt manual mode to close the electrical equipment such as electric light, air-conditioning, so there is and forget to close Situation about closing, causes the waste of electric power, therefore, in order to improve the utilization ratio of electric energy, sophistication and technological meanses, real Now to each lamp (single lamp), or each group of lamp (packet) carries out Based Intelligent Control, including according to staff's presence or absence, realizes The automatic switch of lighting apparatus opens and closes, and by time segment to the adjustment of voltage, control, the working condition to each lamp Realize monitoring etc. automatically, reach the purpose of the comprehensive cost that saves lighting with intelligentized control mode.
Content of the invention
In order to solve above-mentioned technical problem, the present invention provides a kind of economize on electricity of the building based on ZigBee communication technology to control system System, including:CPU 100, temperature sense module 101, luminosity induction unit 102, electromagnetic induction chip 103, ZigBee communication module 104, remote monitoring module 105;Described temperature sense module 101 is arranged on indoor wall, and indoor every 4 It is provided with a temperature sense module 101, temperature sense module 101 is led with CPU 100 in~6 square metres of region Line traffic control connects;Described luminosity induction unit 102 is fixedly mounted in indoor ceiling, between two luminosity induction units 102 Between 4m~5m, luminosity induction unit 102 is passed through wire and is connected with CPU 100 control distance;Described electromagnetism sense Chip 103 is answered to be rectangular configuration, between 2mm~5mm, electromagnetic induction chip 103 is fixedly mounted on each desk to its thickness Upper right comer region, electromagnetic induction chip 103 is connected with CPU 100 polygon control survey;Described ZigBee communication module 104 Interconnect with CPU 100;Described remote monitoring module 105 is connected with ZigBee communication module 104 remotely control.
Further, described CPU 100 adopts CC2530 chip processor.
Further, described temperature sense module 101 includes:Infrared temperature-test sensor 101-1, amplifying circuit 101-2, A/ D modular converter 101-3, address latch module 101-4, key control module 101-5, LED display module 101-6, warning device 101-7;The temperature information that infrared temperature-test sensor 101-1 is gathered by wherein said amplifying circuit 101-2 after enhanced processing, It is sent to A/D modular converter 101-3, the data storage after final conversion is in address latch module 101-4;Described A/D conversion Module 101-3 is connected with CPU 100 control;Described key control module 101-5 is fixedly mounted on wall, and it is high Degree is apart from ground between 1.2m~1.5m;Described LED display module 101-6, warning device 101-7 are all by wire and central authorities Processing unit 100 controls connection.
Further, described luminosity induction unit 102 is provided with S curve intensity control circuit, in luminosity induction unit 102 Luminous intensity measurement element adopt light sensor, described S curve intensity control circuit, light sensor all by wire with central authorities Processing unit 100 controls connection.
Further, described electromagnetic induction chip 103 is molded by macromolecular material pressing mold, the group of electromagnetic induction chip 103 Become composition and manufacture process as follows:
First, electromagnetic induction chip 103 constituent:
Count by weight, 40~95 parts of phenylacetic acid -2- methoxy -4- (2- acrylic) benzene (phenol) ester, (1R, S) is suitable, trans -2, 72~157 parts of 2- dimethyl -3- (2- methyl-1-propylene base) cyclopropane-carboxylic acid-m- phenoxy group ester, 4- [3- (3,4- dimethoxies Base phenyl) -3- (4- fluorophenyl) acryloyl] 43~102 parts of morpholine, (S) alpha-cyano-phenoxy benzyl (1R, 3R) -3- (2,2- Dibromo vinyl) -130~194 parts of 2,2- dimethyl cyclopropane carboxylic acid's ester, (S)-alpha- cyano group -3- phenoxy benzyl-(S) - 2- (4- chlorphenyl) -112~205 parts of 3 Methylbutanoic acid ester, (1R)-trans -2,2- dimethyl -3- (2- methyl-1-propylene base) - 50~121 parts of cyclopropane-carboxylic acid -3- phenoxy benzyl ester, concentration is cyano group-(3- Phenoxyphenyl) first of 32ppm~68ppm Base -3- (2,2- dichloroethylene) -78~139 parts of 2,2- dimethyl cyclopropane carboxylic acid's ester, (S) -3- pi-allyl -2- methyl -4- Oxo-ring amyl- 2- thiazolinyl (1R, 3R) -2,2- dimethyl -3- (2- methyl-1-propylene base) 86~165 parts of cyclopropanecarboxylcompound, Trans-the 3- of 1R- (2,2- dichloroethylene) -2,2- dimethyl cyclopropane carboxylic acid-(2,3,5,6,-tetrafluoro phenyl) methyl ester 92~ 176 parts, 33~80 parts of crosslinking agent, 5- (2- cyano group -4- nitrophenylazo) -6- (2- hydroxyethylamino) -4- methyl -2- [[3- (2- phenoxy group) propyl group] amino] 86~121 parts of -3- pyridine carbonitrile, N- [5- [double (2- methoxy ethyl) amino] -2- [(2- cyano group -4,6- dinitrophenyl) azo] phenyl] 52~143 parts of-acetamide, N- [5- [two [2- (acetoxyl group) ethyls] Amino] -2- [(4- nitrobenzophenone) azo] phenyl] 119~214 parts of benzamide, 2- [[4- [[2- (acetoxyl group) ethyl] fourth Base amino] -2- aminomethyl phenyl] azo] 105~188 parts of -5- nitro -1,3- benzene dicarbonitrile;
Described crosslinking agent is N, N- double (2- ethoxy) methylamine, N- (oxidation diethylidene) -2-[4-morpholinodithio sulfenamide, 2- Any one in chloro- monoacetylaniline;
2nd, the manufacture process of electromagnetic induction chip 103, comprises the steps of:
1st step:Add 3150~3680 parts of the ultra-pure water that electrical conductivity is 4.22 μ S/cm~7.28 μ S/cm in a kettle., start Agitator in reactor, rotating speed is 58rpm~114rpm, starts heat pump, makes reactor temperature rise to 68 DEG C~108 ℃;Sequentially add phenylacetic acid -2- methoxy -4- (2- acrylic) benzene (phenol) ester, (1R, S) suitable, trans -2,2- dimethyl -3- (2- Methyl-1-propylene base) cyclopropane-carboxylic acid-m- phenoxy group ester, 4- [3- (3,4- Dimethoxyphenyl) -3- (4- fluorophenyl) propylene Acyl] morpholine, stirs to being completely dissolved, adjusting pH value is 5.5~8.4, and agitator speed is adjusted to 118rpm~164rpm, temperature For 78 DEG C~155 DEG C, esterification 13~21 hours;
2nd step:Take (S) alpha-cyano-phenoxy benzyl (1R, 3R) -3- (2,2- dibromo vinyl) -2,2- dimethylcyclopropane carboxylic Acid esters, (S)-alpha- cyano group -3- phenoxy benzyl-(S) -2- (4- chlorphenyl) -3 Methylbutanoic acid ester is pulverized, powder grain Footpath is 1300~1900 mesh;Add (1R)-trans -2,2- dimethyl -3- (2- methyl-1-propylene base)-cyclopropane-carboxylic acid -3- benzene Oxy-benzyl ester mixes, and is laid in pallet, tiling thickness be 25mm~36mm, using dosage for 4.4kGy~ 8.3kGy, energy are the alpha ray irradiation 105~166 minutes of 16MeV~23MeV, and the β x ray irradiation x 73 of Isodose~ 146 minutes;
3rd step:It is dissolved in cyano group-(3- Phenoxyphenyl) methyl -3- (2,2- dichloroethylene through the mixed-powder that the 2nd step is processed Base) in -2,2- dimethyl cyclopropane carboxylic acid's ester, add reactor, agitator speed is 82rpm~173rpm, and temperature is 101 DEG C ~152 DEG C, starting vavuum pump makes the vacuum of reactor reach -0.53MPa~1.49MPa, keeps this state response 7~17 little When;Pressure release is simultaneously passed through radon gas, makes reacting kettle inner pressure be 0.42MPa~1.77MPa, insulation standing 12~25 hours;Agitator Rotating speed is promoted to 162rpm~215rpm, simultaneous reactions kettle pressure release to 0MPa;Sequentially add (S) -3- pi-allyl -2- methyl -4- Oxo-ring amyl- 2- thiazolinyl (1R, 3R) -2,2- dimethyl -3- (2- methyl-1-propylene base) cyclopropanecarboxylcompound, the trans -3- of 1R- After (2,2- dichloroethylene) -2,2- dimethyl cyclopropane carboxylic acid-(2,3,5,6,-tetrafluoro phenyl) methyl ester is completely dissolved, plus Enter crosslinking agent stirring mixing so that the hydrophilic lipophilic balance of reactor solution is 4.5~7.6, insulation standing 15~28 hours;
4th step:When agitator speed is for 218rpm~266rpm, sequentially add 5- (2- cyano group -4- nitrophenylazo) -6- (2- hydroxyethylamino) -4- methyl -2- [[3- (2- phenoxy group) propyl group] amino] -3- pyridine carbonitrile, N- [5- [double (2- Methoxy ethyl) amino] -2- [(2- cyano group -4,6- dinitrophenyl) azo] phenyl]-acetamide, N- [5- [two [2- (acetyl Epoxide) ethyl] amino] -2- [(4- nitrobenzophenone) azo] phenyl] benzamide and 2- [[4- [[2- (acetoxyl group) ethyl] Butylamino] -2- aminomethyl phenyl] azo] -5- nitro -1,3- benzene dicarbonitrile, lifting reactor pressure is so as to reach 1.6MPa ~3.2MPa, temperature is 133 DEG C~175 DEG C, polymerisation 9~18 hours;After the completion of reaction, reacting kettle inner pressure is down to 0MPa, is cooled to 34 DEG C~43 DEG C, and discharging enters molding press and can be prepared by electromagnetic induction chip 103.
Further, the invention also discloses a kind of based on ZigBee communication technology building electricity-saving control system work Method, the method includes following step:
1st step:Staff presses total power switch, indoor each electrical equipment and electronic component energising work;Wherein temperature sense mould Infrared temperature-test sensor 101-1 in block 101 is to indoor temperature real-time monitoring, and the temperature signal detecting is sent to puts Big circuit 101-2, the temperature signal after amplified process, after A/D modular converter 101-3 effect, sends CPU to 100;In cooling mode, the temperature value receiving and default value A are compared by CPU 100, work as reception When the temperature value arriving is less than A, CPU 100 controls room conditioning to reduce air quantity output, until temperature value reaches setting Value A;When the temperature value receiving is higher than A, CPU 100 controls room conditioning to strengthen air quantity output, until temperature Value is reduced to setting value A;In a heating mode, the temperature value receiving is carried out by CPU 100 with default value B Relatively, when the temperature value receiving is less than B, CPU 100 controls room conditioning to strengthen air quantity output, until temperature Value reaches setting value B;When the temperature value receiving is higher than B, it is defeated that CPU 100 controls room conditioning to reduce air quantity Go out, until temperature value is reduced to setting value B;The temperature value that CPU 100 receives is shown in LED display module in real time On 101-6;
2nd step:Light sensor in luminosity induction unit 102 is to indoor illumination intensity real-time monitoring;When light sensor inspection Measure indoor illumination intensity and be more than 106cd/m2When, CPU 100 controls S curve intensity control circuit to reduce room light According to intensity to 88cd/m2~98cd/m2;It is less than 66cd/m when light sensor detects indoor illumination intensity2When, central authorities are processed Unit 100 controls S curve intensity control circuit to strengthen indoor illumination intensity to 88cd/m2~98cd/m2
3rd step:The electromagnetic induction chip 103 in the lower desk upper right corner when staff is in place at a desk, is touched with finger, Induced signal is sent to CPU 100, data processing module in CPU 100 by electromagnetic induction chip 103 According to the distribution of electromagnetic induction chip 103 regional location, induced signal is arranged, the computing unit in CPU 100 Calculate the quantity of induced signal in every 2 regions, lamp in 2 is controlled according to induced signal quantity CPU 100 Open number;
4th step:Remote monitoring module 105 passes through ZigBee communication module 104 to indoor electric appliance remote monitoring and operation;Work as interior Unmanned and when electrical equipment is not turned off, administrative staff can be turned off by the remote monitoring module 105 of electronic device terminal.
A kind of building electricity-saving control system based on ZigBee communication technology disclosed by the invention, has an advantage in that:
(1) this system can automatically adjust indoor temperature, intensity of illumination, high degree of automation, energy-conserving and environment-protective;
(2) this system can utilize ZigBee communication technology, remote monitoring can use with operation indoor electric appliance, artificially forgetting When closing indoor electric appliance, can close in time, it is to avoid the unnecessary waste of electric power;
(3) this system according to the densely distributed degree of personnel, the number of intelligentized turn on lights, can realize electric energy optimization should With.
A kind of building electricity-saving control system based on ZigBee communication technology of the present invention, this system automation degree Height, can automatically adjust indoor temperature, illumination brightness, and quantity opened by intelligent management electric light, and application ZigBee communication technology is real Existing remote monitoring and administration.
Brief description
Fig. 1 is a kind of heretofore described building electricity-saving control system schematic diagram based on ZigBee communication technology.
Fig. 2 is heretofore described temperature sense modular system block diagram.
Fig. 3 is heretofore described temperature sense module workflow diagram.
Fig. 4 is heretofore described electromagnetic induction wafer material corrosion resistant erosion degree with use time variation diagram.
In figure 1 above~Fig. 2, CPU 100, temperature sense module 101, infrared temperature-test sensor 101-1, put Big circuit 101-2, A/D modular converter 101-3, address latch module 101-4, key control module 101-5, LED display module 101-6, warning device 101-7, luminosity induction unit 102, electromagnetic induction chip 103, ZigBee communication module 104, long-range prison Control module 105.
Specific embodiment
A kind of building economize on electricity control based on ZigBee communication the technology with reference to the accompanying drawings and examples present invention being provided System processed is further described.
As shown in figure 1, Fig. 1 is a kind of heretofore described building electricity-saving control system based on ZigBee communication technology Schematic diagram.It is seen in fig. 1, that including:CPU 100, temperature sense module 101, luminosity induction unit 102, electromagnetism Sensing chip 103, ZigBee communication module 104, remote monitoring module 105;Described temperature sense module 101 is arranged at indoor wall On wall, in indoor every 4~6 square metres of region, it is provided with a temperature sense module 101, temperature sense module 101 and central authorities Processing unit 100 polygon control survey connects;Described luminosity induction unit 102 is fixedly mounted in indoor ceiling, two luminosity inductions Between 4m~5m, luminosity induction unit 102 is passed through wire and is controlled even with CPU 100 the distance between unit 102 Connect;Described electromagnetic induction chip 103 is rectangular configuration, and between 2mm~5mm, electromagnetic induction chip 103 fixedly mounts its thickness In each desk upper right comer region, electromagnetic induction chip 103 is connected with CPU 100 polygon control survey;Described ZigBee communication module 104 is interconnected with CPU 100;Described remote monitoring module 105 and ZigBee communication mould Block 104 remotely control connects.
CPU 100 adopts CC2530 chip processor.
Luminosity induction unit 102 is provided with S curve intensity control circuit, the luminous intensity measurement unit in luminosity induction unit 102 Part adopts light sensor, and described S curve intensity control circuit, light sensor are all by wire and CPU 100 Control and connect.
As shown in Fig. 2 Fig. 2 is heretofore described temperature sense modular system block diagram.Find out from Fig. 2 or Fig. 1, temperature Degree induction module 101 includes:Infrared temperature-test sensor 101-1, amplifying circuit 101-2, A/D modular converter 101-3, address latch Module 101-4, key control module 101-5, LED display module 101-6, warning device 101-7;Wherein said amplifying circuit The temperature information that infrared temperature-test sensor 101-1 is gathered by 101-2, after enhanced processing, is sent to A/D modular converter 101- 3, the data storage after final conversion is in address latch module 101-4;Described A/D modular converter 101-3 and central authorities process single Unit 100 controls connection;Described key control module 101-5 is fixedly mounted on wall, its height distance ground 1.2m~ 1.5m between;Described LED display module 101-6, warning device 101-7 are all controlled even by wire and CPU 100 Connect.
Of the present invention a kind of based on ZigBee communication technology building electricity-saving control system the course of work be:
1st step:Staff presses total power switch, indoor each electrical equipment and electronic component energising work;Wherein temperature sense mould Infrared temperature-test sensor 101-1 in block 101 is to indoor temperature real-time monitoring, and the temperature signal detecting is sent to puts Big circuit 101-2, the temperature signal after amplified process, after A/D modular converter 101-3 effect, sends CPU to 100;In cooling mode, the temperature value receiving and default value A are compared by CPU 100, work as reception When the temperature value arriving is less than A, CPU 100 controls room conditioning to reduce air quantity output, until temperature value reaches setting Value A;When the temperature value receiving is higher than A, CPU 100 controls room conditioning to strengthen air quantity output, until temperature Value is reduced to setting value A;In a heating mode, the temperature value receiving is carried out by CPU 100 with default value B Relatively, when the temperature value receiving is less than B, CPU 100 controls room conditioning to strengthen air quantity output, until temperature Value reaches setting value B;When the temperature value receiving is higher than B, it is defeated that CPU 100 controls room conditioning to reduce air quantity Go out, until temperature value is reduced to setting value B;The temperature value that CPU 100 receives is shown in LED display module in real time On 101-6;
2nd step:Light sensor in luminosity induction unit 102 is to indoor illumination intensity real-time monitoring;When light sensor inspection Measure indoor illumination intensity and be more than 106cd/m2When, CPU 100 controls S curve intensity control circuit to reduce room light According to intensity to 88cd/m2~98cd/m2;It is less than 66cd/m when light sensor detects indoor illumination intensity2When, central authorities are processed Unit 100 controls S curve intensity control circuit to strengthen indoor illumination intensity to 88cd/m2~98cd/m2
3rd step:The electromagnetic induction chip 103 in the lower desk upper right corner when staff is in place at a desk, is touched with finger, Induced signal is sent to CPU 100, data processing module in CPU 100 by electromagnetic induction chip 103 According to the distribution of electromagnetic induction chip 103 regional location, induced signal is arranged, the computing unit in CPU 100 Calculate the quantity of induced signal in every 2 regions, lamp in 2 is controlled according to induced signal quantity CPU 100 Open number;
4th step:Remote monitoring module 105 passes through ZigBee communication module 104 to indoor electric appliance remote monitoring and operation;Work as interior Unmanned and when electrical equipment is not turned off, administrative staff can be turned off by the remote monitoring module 105 of electronic device terminal.
A kind of building electricity-saving control system based on ZigBee communication technology of the present invention, this system automation degree Height, can automatically adjust indoor temperature, illumination brightness, and quantity opened by intelligent management electric light, and application ZigBee communication technology is real Existing remote monitoring and administration.
The following is the embodiment of the manufacture process of electromagnetic induction chip 103 of the present invention, embodiment is in order to further Present disclosure is described, but should not be construed as limitation of the present invention.Without departing from the spirit and substance of the case in the present invention, The modification that the inventive method, step or condition are made and replacement, belong to the scope of the present invention.
If not specializing, the conventional meanses that in embodiment, technological means used is well known to those skilled in the art.
Embodiment 1
Manufacture electromagnetic induction chip 103 of the present invention according to following steps, and count by weight:
1st step:Add 3150 parts of the ultra-pure water that electrical conductivity is 4.22 μ S/cm in a kettle., start agitator in reactor, turn Speed is 58rpm, starts heat pump, makes reactor temperature rise to 68 DEG C;Sequentially add phenylacetic acid -2- methoxy -4- (2- propylene Base) 40 parts of benzene (phenol) ester, (1R, S) is suitable, trans -2,2- dimethyl -3- (2- methyl-1-propylene base) cyclopropane-carboxylic acid-m- benzene 72 parts of epoxide ester, 4- [3- (3,4- Dimethoxyphenyl) -3- (4- fluorophenyl) acryloyl] 43 parts of morpholine, stirs to completely molten Solution, adjusting pH value is 5.5, and agitator speed is adjusted to 118rpm, and temperature is 78 DEG C, esterification 13 hours;
2nd step:Take (S) alpha-cyano-phenoxy benzyl (1R, 3R) -3- (2,2- dibromo vinyl) -2,2- dimethylcyclopropane carboxylic 130 parts of acid esters, (S)-alpha- cyano group -3- phenoxy benzyl-(S) -2- (4- chlorphenyl) -112 parts of 3 Methylbutanoic acid ester is carried out Pulverize, powder diameter is 1300 mesh;Add (1R)-trans -2,2- dimethyl -3- (2- methyl-1-propylene base)-cyclopropane carboxylic acid 50 parts of acid -3- phenoxy benzyl ester mixes, and is laid in pallet, tiling thickness be 25mm, using dosage be 4.4kGy, energy Measure the alpha ray irradiation 105 minutes for 16MeV, and the β x ray irradiation x of Isodose 73 minutes;
3rd step:Through the 2nd step process mixed-powder be dissolved in concentration be 32ppm cyano group-(3- Phenoxyphenyl) methyl -3- (2, 2- dichloroethylene) in -78 parts of 2,2- dimethyl cyclopropane carboxylic acid's ester, add reactor, agitator speed is 82rpm, temperature For 101 DEG C, starting vavuum pump makes the vacuum of reactor reach -0.53MPa, keeps this state response 7 hours;Pressure release is simultaneously passed through Radon gas, makes reacting kettle inner pressure be 0.42MPa, insulation standing 12 hours;Agitator speed is promoted to 162rpm, simultaneous reactions kettle Pressure release is to 0MPa;Sequentially add (S) -3- pi-allyl -2- methyl -4- oxo-ring amyl- 2- thiazolinyl (1R, 3R) -2,2- dimethyl - 3- (2- methyl-1-propylene base) 86 parts of cyclopropanecarboxylcompound, the trans -3- of 1R- (2,2- dichloroethylene) -2,2- diformazan basic ring third After alkane carboxylic acid-(2,3,5,6 ,-tetrafluoro phenyl) 92 parts of methyl ester is completely dissolved, add the stirring mixing of 33 parts of crosslinking agent so that anti- The hydrophilic lipophilic balance answering kettle solution is 4.5, insulation standing 15 hours;
4th step:When agitator speed is for 218rpm, sequentially add 5- (2- cyano group -4- nitrophenylazo) -6- (2- hydroxyl second Base amino) -4- methyl -2- [[3- (2- phenoxy group) propyl group] amino] 86 parts of -3- pyridine carbonitrile, N- [5- [double (2- first Epoxide ethyl) amino] -2- [(2- cyano group -4,6- dinitrophenyl) azo] phenyl] 52 parts of-acetamide, N- [5- [two [2- (second Acyloxy) ethyl] amino] -2- [(4- nitrobenzophenone) azo] phenyl] 119 parts of benzamide, 2- [[4- [[2- (acetoxyl group) Ethyl] butylamino] -2- aminomethyl phenyl] azo] -5- nitro -1,105 parts of 3- benzene dicarbonitrile, lifting reactor pressure so as to Reach 1.6MPa, temperature is 133 DEG C, polymerisation 9 hours;After the completion of reaction, reacting kettle inner pressure is down to 0MPa, is cooled to 34 DEG C, discharging, enter molding press and can be prepared by electromagnetic induction chip 103;
Described crosslinking agent is N, double (2- ethoxy) methylamine of N-.
Embodiment 2
Manufacture electromagnetic induction chip 103 of the present invention according to following steps, and count by weight:
1st step:Add 3680 parts of the ultra-pure water that electrical conductivity is 7.28 μ S/cm in a kettle., start agitator in reactor, turn Speed is 114rpm, starts heat pump, makes reactor temperature rise to 108 DEG C;Sequentially add phenylacetic acid -2- methoxy -4- (2- third Thiazolinyl) 95 parts of benzene (phenol) ester, (1R, S) is suitable, trans -2,2- dimethyl -3- (2- methyl-1-propylene base) cyclopropane-carboxylic acid-m- 157 parts of phenoxy group ester, 4- [3- (3,4- Dimethoxyphenyl) -3- (4- fluorophenyl) acryloyl] 102 parts of morpholine, stirs to complete Dissolving, adjusting pH value is 8.4, and agitator speed is adjusted to 164rpm, and temperature is 155 DEG C, esterification 21 hours;
2nd step:Take (S) alpha-cyano-phenoxy benzyl (1R, 3R) -3- (2,2- dibromo vinyl) -2,2- dimethylcyclopropane carboxylic 194 parts of acid esters, (S)-alpha- cyano group -3- phenoxy benzyl-(S) -2- (4- chlorphenyl) -205 parts of 3 Methylbutanoic acid ester is carried out Pulverize, powder diameter is 1900 mesh;Add (1R)-trans -2,2- dimethyl -3- (2- methyl-1-propylene base)-cyclopropane carboxylic acid 121 parts of acid -3- phenoxy benzyl ester mixes, and is laid in pallet, tiling thickness be 36mm, using dosage be 8.3kGy, Energy is the alpha ray irradiation 166 minutes of 23MeV, and the β x ray irradiation x of Isodose 146 minutes;
3rd step:Through the 2nd step process mixed-powder be dissolved in concentration be 68ppm cyano group-(3- Phenoxyphenyl) methyl -3- (2, 2- dichloroethylene) in -139 parts of 2,2- dimethyl cyclopropane carboxylic acid's ester, add reactor, agitator speed is 173rpm, temperature Spend for 152 DEG C, starting vavuum pump makes the vacuum of reactor reach 1.49MPa, keeps this state response 17 hours;Pressure release is simultaneously led to Enter radon gas, make reacting kettle inner pressure be 1.77MPa, insulation standing 25 hours;Agitator speed is promoted to 215rpm, simultaneous reactions Kettle pressure release is to 0MPa;Sequentially add (S) -3- pi-allyl -2- methyl -4- oxo-ring amyl- 2- thiazolinyl (1R, 3R) -2,2- diformazan Base -3- (2- methyl-1-propylene base) 165 parts of cyclopropanecarboxylcompound, the trans -3- of 1R- (2,2- dichloroethylene) -2,2- dimethyl After cyclopropane-carboxylic acid-(2,3,5,6 ,-tetrafluoro phenyl) 176 parts of methyl ester is completely dissolved, adds 80 parts of stirring mixing of crosslinking agent, make The hydrophilic lipophilic balance obtaining reactor solution is 7.6, insulation standing 28 hours;
4th step:When agitator speed is for 266rpm, sequentially add 5- (2- cyano group -4- nitrophenylazo) -6- (2- hydroxyl second Base amino) -4- methyl -2- [[3- (2- phenoxy group) propyl group] amino] 121 parts of -3- pyridine carbonitrile, N- [5- [double (2- first Epoxide ethyl) amino] -2- [(2- cyano group -4,6- dinitrophenyl) azo] phenyl] 143 parts of-acetamide, N- [5- [two [2- (acetoxyl group) ethyl] amino] -2- [(4- nitrobenzophenone) azo] phenyl] 214 parts of benzamide, 2- [[4- [[2- (acetyl oxygen Base) ethyl] butylamino] -2- aminomethyl phenyl] azo] -5- nitro -1,188 parts of 3- benzene dicarbonitrile, lift reactor pressure, make It reaches 3.2MPa, and temperature is 175 DEG C, polymerisation 18 hours;After the completion of reaction, reacting kettle inner pressure is down to 0MPa, cooling To 43 DEG C, discharging, enter molding press and can be prepared by electromagnetic induction chip 103;
Described crosslinking agent is N- (oxidation diethylidene) -2-[4-morpholinodithio sulfenamide.
Embodiment 3
Manufacture electromagnetic induction chip 103 of the present invention according to following steps, and count by weight:
1st step:Add 3420 parts of the ultra-pure water that electrical conductivity is 5.58 μ S/cm in a kettle., start agitator in reactor, turn Speed is 88rpm, starts heat pump, makes reactor temperature rise to 83 DEG C;Sequentially add phenylacetic acid -2- methoxy -4- (2- propylene Base) 62 parts of benzene (phenol) ester, (1R, S) is suitable, trans -2,2- dimethyl -3- (2- methyl-1-propylene base) cyclopropane-carboxylic acid-m- benzene 112 parts of epoxide ester, 4- [3- (3,4- Dimethoxyphenyl) -3- (4- fluorophenyl) acryloyl] 73 parts of morpholine, stirs to completely molten Solution, adjusting pH value is 7.3, and agitator speed is adjusted to 142rpm, and temperature is 116 DEG C, esterification 17 hours;
2nd step:Take (S) alpha-cyano-phenoxy benzyl (1R, 3R) -3- (2,2- dibromo vinyl) -2,2- dimethylcyclopropane carboxylic 160 parts of acid esters, (S)-alpha- cyano group -3- phenoxy benzyl-(S) -2- (4- chlorphenyl) -158 parts of 3 Methylbutanoic acid ester is carried out Pulverize, powder diameter is 1600 mesh;Add (1R)-trans -2,2- dimethyl -3- (2- methyl-1-propylene base)-cyclopropane carboxylic acid 85 parts of acid -3- phenoxy benzyl ester mixes, and is laid in pallet, tiling thickness be 30mm, using dosage be 6.4kGy, energy Measure the alpha ray irradiation 135 minutes for 19MeV, and the β x ray irradiation x of Isodose 104 minutes;
3rd step:Through the 2nd step process mixed-powder be dissolved in concentration be 47ppm cyano group-(3- Phenoxyphenyl) methyl -3- (2, 2- dichloroethylene) in -108 parts of 2,2- dimethyl cyclopropane carboxylic acid's ester, add reactor, agitator speed is 127rpm, temperature Spend for 126 DEG C, starting vavuum pump makes the vacuum of reactor reach 0.85MPa, keeps this state response 12 hours;Pressure release is simultaneously led to Enter radon gas, make reacting kettle inner pressure be 1.05MPa, insulation standing 18 hours;Agitator speed is promoted to 185rpm, simultaneous reactions Kettle pressure release is to 0MPa;Sequentially add (S) -3- pi-allyl -2- methyl -4- oxo-ring amyl- 2- thiazolinyl (1R, 3R) -2,2- diformazan Base -3- (2- methyl-1-propylene base) 126 parts of cyclopropanecarboxylcompound, the trans -3- of 1R- (2,2- dichloroethylene) -2,2- dimethyl After cyclopropane-carboxylic acid-(2,3,5,6 ,-tetrafluoro phenyl) 132 parts of methyl ester is completely dissolved, adds 58 parts of stirring mixing of crosslinking agent, make The hydrophilic lipophilic balance obtaining reactor solution is 6.1, insulation standing 22 hours;
4th step:When agitator speed is for 235rpm, sequentially add 5- (2- cyano group -4- nitrophenylazo) -6- (2- hydroxyl second Base amino) -4- methyl -2- [[3- (2- phenoxy group) propyl group] amino] 106 parts of -3- pyridine carbonitrile, N- [5- [double (2- first Epoxide ethyl) amino] -2- [(2- cyano group -4,6- dinitrophenyl) azo] phenyl] 93 parts of-acetamide, N- [5- [two [2- (second Acyloxy) ethyl] amino] -2- [(4- nitrobenzophenone) azo] phenyl] 169 parts of benzamide, 2- [[4- [[2- (acetoxyl group) Ethyl] butylamino] -2- aminomethyl phenyl] azo] -5- nitro -1,145 parts of 3- benzene dicarbonitrile, lifting reactor pressure so as to Reach 2.4MPa, temperature is 153 DEG C, polymerisation 13 hours;After the completion of reaction, reacting kettle inner pressure is down to 0MPa, is cooled to 38 DEG C, discharging, enter molding press and can be prepared by electromagnetic induction chip 103;
Described crosslinking agent is the chloro- monoacetylaniline of 2-.
Reference examples
Reference examples are the electromagnetic induction chip of certain brand commercially available.
Embodiment 4
Electromagnetic induction chip described in the electromagnetic induction chip 103 that prepare embodiment 1~3 and reference examples is carried out using effect Fruit contrasts.The two Unit Weight, reaction time, transfer rate, wear-resistant rate are counted, result is as shown in table 1.
As seen from Table 1, electromagnetic induction chip 103 of the present invention, its Unit Weight, the reaction time, transfer rate, resistance to The indexs such as wear rate are superior to the product of prior art production.
Additionally, as shown in figure 4, being that electromagnetic induction chip 103 material corrosion resistant erosion degree of the present invention becomes with use time The statistics changed.In figure is found out, electromagnetic induction chip 103 used by embodiment 1~3, and its material corrosion resistant erosion degree changes with use time Degree is significantly better than existing product.

Claims (6)

1. a kind of building electricity-saving control system based on ZigBee communication technology, including:CPU (100), temperature sense Answer module (101), luminosity induction unit (102), electromagnetic induction chip (103), ZigBee communication module (104), remote monitoring Module (105);It is characterized in that, described temperature sense module (101) is arranged on indoor wall, indoor every 4~6 square metres It is provided with a temperature sense module (101), temperature sense module (101) and CPU (100) wire control in region System connects;Described luminosity induction unit (102) is fixedly mounted in indoor ceiling, between two luminosity induction units (102) Between 4m~5m, luminosity induction unit (102) is passed through wire and is connected with CPU (100) control distance;Described electricity Magnetic induction chip (103) is rectangular configuration, and between 2mm~5mm, electromagnetic induction chip (103) is fixedly mounted on often its thickness Individual desk upper right comer region, electromagnetic induction chip (103) is connected with CPU (100) polygon control survey;Described ZigBee communication module (104) is interconnected with CPU (100);Described remote monitoring module (105) and ZigBee Communication module (104) remotely control connects.
2. a kind of building electricity-saving control system based on ZigBee communication technology according to claim 1 it is characterised in that Described CPU (100) adopts CC2530 chip processor.
3. a kind of building electricity-saving control system based on ZigBee communication technology according to claim 1 it is characterised in that Described temperature sense module (101) includes:Infrared temperature-test sensor (101-1), amplifying circuit (101-2), A/D modular converter (101-3), address latch module (101-4), key control module (101-5), LED display module (101-6), warning device (101-7);The temperature information that infrared temperature-test sensor (101-1) gathers is passed through and amplifies by wherein said amplifying circuit (101-2) After process, it is sent to A/D modular converter (101-3), the data storage after final conversion is in address latch module (101-4); Described A/D modular converter (101-3) is connected with CPU (100) control;Described key control module (101-5) is fixing It is arranged on wall, its height distance ground is between 1.2m~1.5m;Described LED display module (101-6), warning device (101-7) all controlled with CPU (100) by wire and be connected.
4. a kind of building electricity-saving control system based on ZigBee communication technology according to claim 1 it is characterised in that Described luminosity induction unit (102) is provided with S curve intensity control circuit, the luminous intensity measurement unit in luminosity induction unit (102) Part adopts light sensor, and described S curve intensity control circuit, light sensor are all by wire and CPU (100) control and connect.
5. a kind of building electricity-saving control system based on ZigBee communication technology according to claim 1 it is characterised in that Described electromagnetic induction chip (103) is molded by macromolecular material pressing mold, the constituent of electromagnetic induction chip (103) and manufacturing Journey is as follows:
First, electromagnetic induction chip (103) constituent:
Count by weight, 40~95 parts of phenylacetic acid -2- methoxy -4- (2- acrylic) benzene (phenol) ester, (1R, S) is suitable, trans -2, 72~157 parts of 2- dimethyl -3- (2- methyl-1-propylene base) cyclopropane-carboxylic acid-m- phenoxy group ester, 4- [3- (3,4- dimethoxies Base phenyl) -3- (4- fluorophenyl) acryloyl] 43~102 parts of morpholine, (S) alpha-cyano-phenoxy benzyl (1R, 3R) -3- (2,2- Dibromo vinyl) -130~194 parts of 2,2- dimethyl cyclopropane carboxylic acid's ester, (S)-alpha- cyano group -3- phenoxy benzyl-(S) - 2- (4- chlorphenyl) -112~205 parts of 3 Methylbutanoic acid ester, (1R)-trans -2,2- dimethyl -3- (2- methyl-1-propylene base) - 50~121 parts of cyclopropane-carboxylic acid -3- phenoxy benzyl ester, concentration is cyano group-(3- Phenoxyphenyl) first of 32ppm~68ppm Base -3- (2,2- dichloroethylene) -78~139 parts of 2,2- dimethyl cyclopropane carboxylic acid's ester, (S) -3- pi-allyl -2- methyl -4- Oxo-ring amyl- 2- thiazolinyl (1R, 3R) -2,2- dimethyl -3- (2- methyl-1-propylene base) 86~165 parts of cyclopropanecarboxylcompound, Trans-the 3- of 1R- (2,2- dichloroethylene) -2,2- dimethyl cyclopropane carboxylic acid-(2,3,5,6,-tetrafluoro phenyl) methyl ester 92~ 176 parts, 33~80 parts of crosslinking agent, 5- (2- cyano group -4- nitrophenylazo) -6- (2- hydroxyethylamino) -4- methyl -2- [[3- (2- phenoxy group) propyl group] amino] 86~121 parts of -3- pyridine carbonitrile, N- [5- [double (2- methoxy ethyl) amino] -2- [(2- cyano group -4,6- dinitrophenyl) azo] phenyl] 52~143 parts of-acetamide, N- [5- [two [2- (acetoxyl group) ethyls] Amino] -2- [(4- nitrobenzophenone) azo] phenyl] 119~214 parts of benzamide, 2- [[4- [[2- (acetoxyl group) ethyl] fourth Base amino] -2- aminomethyl phenyl] azo] 105~188 parts of -5- nitro -1,3- benzene dicarbonitrile;
Described crosslinking agent is N, N- double (2- ethoxy) methylamine, N- (oxidation diethylidene) -2-[4-morpholinodithio sulfenamide, 2- Any one in chloro- monoacetylaniline;
2nd, the manufacture process of electromagnetic induction chip (103), comprises the steps of:
1st step:Add 3150~3680 parts of the ultra-pure water that electrical conductivity is 4.22 μ S/cm~7.28 μ S/cm in a kettle., start Agitator in reactor, rotating speed is 58rpm~114rpm, starts heat pump, makes reactor temperature rise to 68 DEG C~108 ℃;Sequentially add phenylacetic acid -2- methoxy -4- (2- acrylic) benzene (phenol) ester, (1R, S) suitable, trans -2,2- dimethyl -3- (2- Methyl-1-propylene base) cyclopropane-carboxylic acid-m- phenoxy group ester, 4- [3- (3,4- Dimethoxyphenyl) -3- (4- fluorophenyl) propylene Acyl] morpholine, stirs to being completely dissolved, adjusting pH value is 5.5~8.4, and agitator speed is adjusted to 118rpm~164rpm, temperature For 78 DEG C~155 DEG C, esterification 13~21 hours;
2nd step:Take (S) alpha-cyano-phenoxy benzyl (1R, 3R) -3- (2,2- dibromo vinyl) -2,2- dimethylcyclopropane carboxylic Acid esters, (S)-alpha- cyano group -3- phenoxy benzyl-(S) -2- (4- chlorphenyl) -3 Methylbutanoic acid ester is pulverized, powder grain Footpath is 1300~1900 mesh;Add (1R)-trans -2,2- dimethyl -3- (2- methyl-1-propylene base)-cyclopropane-carboxylic acid -3- benzene Oxy-benzyl ester mixes, and is laid in pallet, tiling thickness be 25mm~36mm, using dosage for 4.4kGy~ 8.3kGy, energy are the alpha ray irradiation 105~166 minutes of 16MeV~23MeV, and the β x ray irradiation x 73 of Isodose~ 146 minutes;
3rd step:It is dissolved in cyano group-(3- Phenoxyphenyl) methyl -3- (2,2- dichloroethylene through the mixed-powder that the 2nd step is processed Base) in -2,2- dimethyl cyclopropane carboxylic acid's ester, add reactor, agitator speed is 82rpm~173rpm, and temperature is 101 DEG C ~152 DEG C, starting vavuum pump makes the vacuum of reactor reach -0.53MPa~1.49MPa, keeps this state response 7~17 little When;Pressure release is simultaneously passed through radon gas, makes reacting kettle inner pressure be 0.42MPa~1.77MPa, insulation standing 12~25 hours;Agitator Rotating speed is promoted to 162rpm~215rpm, simultaneous reactions kettle pressure release to 0MPa;Sequentially add (S) -3- pi-allyl -2- methyl -4- Oxo-ring amyl- 2- thiazolinyl (1R, 3R) -2,2- dimethyl -3- (2- methyl-1-propylene base) cyclopropanecarboxylcompound, the trans -3- of 1R- After (2,2- dichloroethylene) -2,2- dimethyl cyclopropane carboxylic acid-(2,3,5,6,-tetrafluoro phenyl) methyl ester is completely dissolved, plus Enter crosslinking agent stirring mixing so that the hydrophilic lipophilic balance of reactor solution is 4.5~7.6, insulation standing 15~28 hours;
4th step:When agitator speed is for 218rpm~266rpm, sequentially add 5- (2- cyano group -4- nitrophenylazo) -6- (2- hydroxyethylamino) -4- methyl -2- [[3- (2- phenoxy group) propyl group] amino] -3- pyridine carbonitrile, N- [5- [double (2- Methoxy ethyl) amino] -2- [(2- cyano group -4,6- dinitrophenyl) azo] phenyl]-acetamide, N- [5- [two [2- (acetyl Epoxide) ethyl] amino] -2- [(4- nitrobenzophenone) azo] phenyl] benzamide and 2- [[4- [[2- (acetoxyl group) ethyl] Butylamino] -2- aminomethyl phenyl] azo] -5- nitro -1,3- benzene dicarbonitrile, lifting reactor pressure is so as to reach 1.6MPa ~3.2MPa, temperature is 133 DEG C~175 DEG C, polymerisation 9~18 hours;After the completion of reaction, reacting kettle inner pressure is down to 0MPa, is cooled to 34 DEG C~43 DEG C, and discharging enters molding press and can be prepared by electromagnetic induction chip (103).
6. a kind of method of work of the building electricity-saving control system based on ZigBee communication technology is it is characterised in that the method bag Include following step:
1st step:Staff presses total power switch, indoor each electrical equipment and electronic component energising work;Wherein temperature sense mould Infrared temperature-test sensor (101-1) in block (101) is to indoor temperature real-time monitoring, and the temperature signal detecting is sent To amplifying circuit (101-2), the temperature signal after amplified process, after A/D modular converter (101-3) effect, sends central authorities to Processing unit (100);In cooling mode, the temperature value receiving is carried out by CPU (100) with default value A Relatively, when the temperature value receiving is less than A, CPU (100) controls room conditioning to reduce air quantity output, until temperature Angle value reaches setting value A;When the temperature value receiving is higher than A, CPU (100) controls room conditioning to strengthen air quantity Output, until temperature value is reduced to setting value A;In a heating mode, CPU (100) by the temperature value receiving with Default value B is compared, and when the temperature value receiving is less than B, CPU (100) controls room conditioning to strengthen Air quantity exports, until temperature value reaches setting value B;When the temperature value receiving is higher than B, CPU (100) controls Room conditioning reduces air quantity output, until temperature value is reduced to setting value B;The temperature value that CPU (100) receives It is shown in real time in LED display module (101-6);
2nd step:Light sensor in luminosity induction unit (102) is to indoor illumination intensity real-time monitoring;Work as light sensor Indoor illumination intensity is detected and be more than 106cd/m2When, CPU (100) controls S curve intensity control circuit to reduce room Interior intensity of illumination is to 88cd/m2~98cd/m2;It is less than 66cd/m when light sensor detects indoor illumination intensity2When, central authorities Processing unit (100) controls S curve intensity control circuit to strengthen indoor illumination intensity to 88cd/m2~98cd/m2
3rd step:The electromagnetic induction chip in the lower desk upper right corner when staff is in place at a desk, is touched with finger (103), induced signal is sent to CPU (100) by electromagnetic induction chip (103), in CPU (100) Data processing module is arranged to induced signal according to the distribution of electromagnetic induction chip (103) regional location, CPU (100) computing unit in calculates the quantity of induced signal in every 2 regions, according to induced signal quantity CPU (100) control the unlatching number of lamp in 2;
4th step:Remote monitoring module (105) passes through ZigBee communication module (104) to indoor electric appliance remote monitoring and operation;When Indoor unmanned and when electrical equipment is not turned off, administrative staff can be by remote monitoring module (105) Jiang Qiguan of electronic device terminal Close.
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